The invention relates to operating devices for manually actuating lifting devices.
For instance, a switch for manually actuating lifting devices is known from German application laid open DE 103 31 130 A1. The switch has a switch housing, in which several spring-loaded switching elements—such as for the lifting and lowering functions of a lifting device—are arranged. Each switching element includes of an electrical push button switch and a mechanical pressure switch for its actuation. The mechanical pressure switch is basically made up of a switch tappet and a sleeve. The switch tappet is guided in the sleeve for actuating the electrical push button switch, configured as a microswitch. The switch tappet is buttressed against the push button or a floor of the switch housing by a spring element in the form of a helical spring. The pressure switch can be one-step or multiple-step in configuration, starting from an off position, the switch tappet can be moved into a first on position and then to at least one additional on position. Accordingly, corresponding electrical push buttons or multiple-step push buttons are then actuated by the switch tappet in each of the on positions. In the off position, the switch tappet protrudes furthest out from the sleeve and it is then moved in the direction of the sleeve to reach the first or the additional on positions. In the last on position, the switch tappet still protrudes from the sleeve so that it can be felt by the user's thumb.
Furthermore, from the Spanish utility model ES 101 83 51 U there is known another switch for the manual actuating of lifting devices, which likewise has switching elements arranged in a switch housing with electrical push buttons and a mechanical pressure switch. The mechanical pressure switch also has a switch tappet and a sleeve, in which the switch tappet is guided for an activation of the electrical push button. Furthermore, the pressure switch here is also sealed off from the switch housing with a flexible covering element. Before the flexible covering element is mounted, the sleeve provided with an outer thread is screwed into an opening in the front surface of the switch housing until a sealing ring, bearing against a peripheral rim on the outside of the sleeve, comes to bear against the inside of the front surface of the switch housing. The covering element is then screwed from the outside onto the rest of the outer thread protruding from the front surface of the switch housing until the covering element comes to bear flush against the front surface of the switch housing. For this, the covering element has an inwardly directed peripheral groove in the region of its connection opening, in which is inserted a connection ring having an inner thread.
The protective caps of the switching elements are often subjected to special strain and often need to be replaced on account of wear.
The present invention provides an operating device for manual actuating of lifting devices, in which the covering elements of the switching elements are easy to assemble and replace.
In connection with industrial applications it is desirable for the user to have to move through an actuating path—for example, with his thumb—between the off position and the respective on positions so that even when wearing gloves he can safely operate the switch. Furthermore, it is advantageous for the switching element to return by itself to the off position so that the guided movement is activated only as long as the operator holds the switching element in the on position against its restoring force.
According to one aspect of the invention, an operating device for manually actuating lifting devices includes at least one switching element arranged in a switch housing. The switching element includes a tappet, which protrudes from the switch housing, is guided in a sleeve, and is covered by a covering element having a threaded ring, wherein the sleeve protrudes outside through an opening in the switch housing, the sleeve is held in the switch housing through a threaded joint, and the covering element is screwed to the sleeve in a detachable manner through the threaded ring of the covering element, an easy installation and replacement capability for the covering elements of the switching elements is achieved in that the sleeve has an outwardly extending collar, which in the installed state bears against an outer surface of the switch housing, and the sleeve is held on the switch housing in a detachable manner by a fastening ring, which in the installed state bears against an inner surface of the switch housing.
The opening of the switch housing in order to replace a covering element can be avoided. This opening otherwise would constitute a special expense to be done with special care by a technician, so as to cause no damage to the installed electrical subassemblies and so that the switch housing has the necessary sealing action after being put together. To perform this work, the switch needs to be removed on site and taken to a repair shop. Also, for the assembly of the covering elements, the sleeve is held securely in the switch housing by the fastening ring. This simplifies the assembly process. Furthermore, the switching element remains functional even without the covering element.
According to another aspect of the present invention, the switch housing does not need to be opened for servicing: repair can be done at the site of use of the operating device by removing a damaged covering element and replacing it with a new one.
In another embodiment of the invention, a switch housing has two switching elements, each being two-step in configuration. Thus, one can use this to control a lifting device in the lifting and lowering direction and, owing to the two-step design, each switching element can be placed in a first on position such as for slow duty—and a second on position such as for fast duty. Such switches are also useful for control of traversing gears or cranes.
The mechanical pressure switches are each secured via a sleeve to the switch housing. For this, round openings are provided in a front surface of the switch housing, into which the pressure switches are inserted from the outside. So that the pressure switch does not drop inside the switch housing through the opening while being assembled, the sleeves of the pressure switches have an outward pointing peripheral collar at their outer end, which comes to bear against the front surface of the switch housing. In order to fasten the pressure switch against the switch housing, the inner end of the sleeve is provided with an external thread. A fastening ring such as a nut is screwed onto the external thread, which comes to bear against the inside of the front surface of the switch housing and thus tightens the collar against the front surface of the switch housing.
For industrial applications, the electrical push buttons and the pressure switches may be installed in a switch housing that is tight or sealed in order to protect against external influences and dirt. Furthermore, the switch housing is configured such that the switch tappets protrude from the switch housing, thus providing some play for the actuating path of the pressure switch.
In order to seal off the switch tappets protruding from the switch housing against the tight switch housing, the switch tappets are surrounded by a flexible covering element in the manner of a protective cap, which is tightly connected to the switch housing. For this, the covering element is configured with a round connection opening. Seen in cross section, the covering has a cross section somewhat like a truncated cone, the smaller base surface lying against the switch tappet and the larger base surface pointing toward the connection opening. In the region of the connection opening, the covering element has an inwardly pointing rim extending parallel to the smaller base surface of the covering element. This rim is dimensioned such that it has roughly the dimensions of the sealing surface of the collar of the sleeve facing the switch housing. Before the pressure switch is inserted into the opening of the switch housing, the covering element is inverted over the collar of the sleeve, after which the sleeve of the pressure switch is inserted into the round opening of the switch housing and then the fastening ring is tightened from the inside. The rim of the covering element is clamped in this way between the front surface of the switch housing and the sealing surface of the collar and thus the opening of the switch housing is closed tight. To prevent the rim from slipping out from the region between the collar and the front surface, the front surface rebounds in the manner of an annular recess in which the outer circumference of the rim of the covering element comes to bear.
Advantageously, it may be provided that the sleeve has a first outer thread and a second outer thread; the first outer thread and the second outer thread are separated from each other by the collar, in the installed state the fastening ring engages with the first outer thread and in the installed state the threaded ring engages with the second outer thread. In this way, the switching element is held securely in the switch housing.
Optionally, the sleeve is secured against twisting relative to the switch housing. For this, the sleeve preferably has a radially outwardly protruding lug in the area of the collar, which engages with a recess that is arranged in the switch housing. Thanks to this twist protection, the installing of the covering element does not remove or loosen the screw connection of the sleeve with the switch housing via the fastening ring.
Optionally, the threaded ring of the covering element is buttressed against an outer surface of the switch housing in the installed state.
In one embodiment, the covering element is fashioned as a hat with a connection ring, the threaded ring is enclosed by the connection ring, and one part of the connection ring is clamped between the outer surface of the switch housing and the threaded ring, which produces the sealing action. Moreover, a secure joint is ensured between threaded ring and connection ring.
Furthermore, the threaded ring can also have an outer toothing or toothed surface on its outer circumference and the connection ring an inner toothing or toothed surface on the inside. This accomplishes a secure transmission of the installation forces from the installation tool via the connection ring to the threaded ring.
Optionally, the switch housing has a recess with an encompassing wall in the region of the opening for the switching element, which lies opposite a lower part of the connection ring. This prevents the connection ring from being forced out from beneath the threaded ring, losing the sealing action.
Where the covering element is provided with an outer profile (e.g., a toothing or toothed surface) for an assembly tool in the region of its connection ring, the covering element can easily be screwed onto the sleeve and be loosened from it. The assembly tool has a corresponding inner profile (e.g., a toothing or toothed surface) to cooperate with the outer profile of the covering element. The outer profile on the connection ring can be easily reached from the assembly tool, since even in the installed state the outer profile on the connection ring is arranged outside of the region of the connection ring that lies opposite the encompassing wall. Thus, the required tightening torques for the threaded ring can be safely applied. Also, a covering element that is surrounded by neighboring switching elements and shape elements of the switch housing can be installed or removed with the assembly tool in the manner of a socket wrench. The switch housings have the shape elements to provide a protection against accidental actuating of the switching elements. To accomplish this protection, the switching elements are recessed in the shape elements of the switch housing in the form of depressions. Here as well, the covering elements can easily be manipulated with the assembly tool.
In addition, it is specified that the covering element in the region of its connection ring is configured as conically increasing in diameter in the direction of the switch housing. The form fit between assembly tool and connection ring is thus strengthened by pushing the assembly tool in the direction of the covering element.
Optionally, the connection ring has an inner toothing or toothed surface, which engages with an outer toothing or toothed surface of the threaded ring. In this way, the installation forces can be safely transmitted from the assembly tool to the connection ring and on to the threaded ring.
Optionally, the covering element is secured on the switch housing by an adhesive or bonding connection.
In regard to a tool for installation and disassembly of the aforementioned covering element of the operating device, it is proposed that the inner profile of the tool be configured conically in the axial activating direction of the switching element.
Depending on the configuration of the covering element, it can be provided advantageously that the tool has an inner profile shaped complementary to the outer profile of the connection ring in the manner of a socket wrench, the tool encloses the covering element while it is being installed, and/or the inner profile is configured as a toothing or toothed surface, with the flanks of the teeth being preferably more steep in the disassembly direction.
These and other objects, advantages and features of this invention will become apparent upon review of the following specification in conjunction with the drawings.
It is also conceivable for the symbol carrying element 5 to be a round or angular placard that is glued to the actuating surface 4a or clamped in appropriately provided grooves. The grooves in this case preferably have a continuous circumference to ensure a firm holding of the symbol carrying element 5.
The switching element 2 shown in
Of the two bottom switching elements 2, the left one is assigned a warning signal and the right one an emergency stop function. The upper four switching elements 2, by which the drive units of the crane are controlled, are configured as so-called two-stage switches, i.e., besides an off position there is a first on position and a second on position, in which each drive unit can be actuated in two speeds in one direction of movement. Basically, it is also possible to fashion the switching elements 2 so that drive units can be steered continuously.
For safety reasons, the switching elements 2 of an operating device 1 for the manual actuating of lifting devices are designed so that a switching element 2, once activated, returns at once to the off position again once no more pressure is applied to the switching element 2. For this purpose, each switching element 2 is biased by a spring element 6 in the direction of the switched-off basic position.
As is further evident from
Due to this spatial separation of the actual electrical switch by the first micro switch 7 from the mechanical switching by means of the pressure activation mechanism 8, it becomes possible to use microswitches 7 that require only small switching paths and low switching forces. The large switching paths of at least 5 mm or so that are prescribed for a safe handling, distinct locking positions for fast and slow duty, and easily perceived switching forces can be easily and inexpensively accomplished in this embodiment by the kinematics of the pressure activation mechanism 8 that is connected in series to the microswitch 7.
The sample embodiment shown for an operating device for the manual actuating of lifting devices is furthermore configured such that another commonly-shared second electrical microswitch 10 is assigned to the pairs of upper and middle switching elements 2, by which a fast duty of the traversing movement of the length of chain or cable can be activated for the particular direction of movement. This second common microswitch 10 is activated by the respective pressure activation mechanism 8 for the desired direction of movement. Of course, it is also possible to assign its own second microswitch 10 to each switching element 2.
In any case, the pressure activation mechanism 8 is designed so that the second microswitch 10 can only be actuated in time sequence after the actuation of one of the first microswitches 7, that is, the lifting device can be switched first to the slow lifting or lowering duty or traversing duty before the fast duty can be switched on by activating the second microswitch 10.
To execute the consecutive switching function, namely, the actuation of the first electrical microswitch 7 of the switching element 2 on the one hand and the subsequent actuation of the second microswitch 10 on the other hand, the pressure activation mechanisms 8 of the switching elements 2 each include a tappet 11, biased by the spring element 6 with respect to the corresponding electrical switching means in the form of the first microswitch 7 of the switching element 2, and an inner tappet 13 that is led in a borehole 12 of the tappet 11, while the inner tappet 13 is buttressed against the tappet 11 by a spring element 14 mounted in the borehole 12. In this way, the inner tappet 13 can move coaxially in the tappet 11.
The actuating of the above-described operating device 1 for manual actuating of lifting devices is done as follows:
While exerting a pressure on the covering element 4 that spans a switching element 2, the pressure is transmitted to the tappet 11 of the pressure activation mechanism 8 and the tappet 11 moves against the restoring force of the spring element 6 in the direction of the corresponding first electrical microswitch 7, especially its switch tappet 15, of the switching element 2. The inner tappet 13 mounted via the spring element 14 in the tappet 11 is carried along unloaded during this movement, until the inner tappet 13 conies up against the first microswitch 7 or its switch tappet 15 by its bearing surface 13a and activates the electrical circuit. The inner tappet 13 is mounted coaxially to the switch tappet 15 of the first microswitch 7 in this process.
If further pressure is now exerted on the tappet 11 of the pressure activation mechanism 8, this pressure has the effect of compressing the spring element 14 by the inner tappet 13 lying against the first microswitch 7, so that the tappet 11 is pressed further into the switch housing 3 against the restoring force of the spring element 6, until a bearing surface 11a of the tappet 11 comes up against the switch tappet 15 of the second microswitch 10 and thus activates the fast duty.
To prevent moisture and/or dirt from getting into the switch housing 3, the pressure activation mechanisms 8 are sealed off from the outside of the switch housing 3 with the flexible covering element 4 already shown in
The covering element 4 has a circular connection opening 16 at its end opposite the actuating surface 4a, being bounded by an encompassing connection ring 4c. The connection ring 4c adjoins the end of the side wall 4b opposite the actuating surface 4a and extends from the side wall 4b inwardly in the direction of the connection opening 16. Thus, the connection ring 4c forms a flat annular sealing surface 4d facing the switch housing 3 and an opposite, likewise flat annular connection surface 4e facing away from the switch housing 3. The sealing surface 4d and the connection surface 4e lie opposite and turned away from each other.
Furthermore, the connection ring 4c encloses in U-shaped or L-shaped fashion a threaded ring 17, which has an essentially rectangular cross section and an internal thread 17a on its inner circumference. The threaded ring 17 is form-fitted and held in the elastic connection ring 4c of the covering element 4.
For the fastening of the switching elements 2 in the switch housing, there are six round openings 18 arranged in a front surface 3a of the switch housing 3, into which the pressure activation mechanism 8 is inserted from the outside. For this, the pressure activation mechanism 8 has a cylindrical sleeve 19, in which the tappet 11 is held and led movably between its end positions. So that the sleeve 19 is not pushed from the outside through the respective opening 18, it has in its middle region a continuous annular collar 19a. Thus, the collar 19a extending radially outward from the sleeve 19 forms a second annular surface 19b, which in the installed state of the switch element 2 comes to rest against the outer surface 3c of the front surface 3a, which bounds the opening 18 for the sleeve 19.
In order to hold the pressure activation mechanism 8 in the respective opening 18, the region of the sleeve 19 bordering on the collar 19a and extending inward across the inner surface 3b of the front surface 3a of the switch housing 3 has a first external thread 19c. Thus, the sleeve 19 is also at the same time a housing pass-through for the tappet 11. On the first external thread 19c of the sleeve 19 is a fastening ring 23 with its internal thread 23a. The fastening ring 23 is steplike in cross section and divided into a first annular segment 23c and a second annular segment 23d (see
Due to the screwed-on fastening ring 23, the collar 19a is pressed by its annular surface 19b against the outer surface 3c of the front surface 3a of the switch housing 3 and the fastening ring 23 is pressed by its bearing surface 23b against the inner surface 3d of the switch housing 3. The inner surface 3b of the front surface 3a, the outer surface 3c of the front surface 3a, the annular surface 19b of the collar 19a and the bearing surface 23b of the fastening ring 23 are oriented basically parallel to each other.
Furthermore, the region of the sleeve 19 bordering on the collar 19a and extending outward across the outer surface 3c of the front surface 3a of the switch housing 3 has a second external thread 19d. On the second external thread 19d of the sleeve 19 is screwed the covering element 4 by its threaded ring 17. In this way, the sealing surface 4d of the connection ring 4c is pressed against the outer surface 3c of the switch housing 3 and the threaded ring 17 against the connection surface 4e of the connection ring 4c. The sealing surface 4d of the connection ring 4c, the outer surface 3c of the switch housing 3, the pressing surface of the threaded ring 17 and the connection surface 4e of the connection ring 4c are oriented basically parallel to each other. Thus, the opening 18 is tightly closed by the covering element 4 with the threaded ring 17.
Due to this design configuration, the functions of mechanical fastening of the switching element 2 in the switch housing 3 and sealing off of the switching element 2 from the switch housing 3 are separated from each other. The fastening ring 23 takes charge of the mechanical fastening and the threaded ring 17 of the sealing.
Moreover, the front surface 3a of the switch housing 3 is provided with a peripheral trapezoidal projection 22, which “digs in” from the bottom in the covering element 4 in the region of the sealing surface 4d when assembled, so that the covering element 4 is fixed horizontally in its position.
It is also noticeable from
In addition, it can be provided that the covering element 4 is secured to the switch housing 3 by an adhesive or bonding connection. In particular, such an adhesive or bonding connection is provided between the sealing surface 4d of the covering element 4 and the outer surface 3c of the switch housing 3.
To prevent a twisting of the sleeve 19 when screwing on the covering element 4, the sleeve 19 has a lug 24 (see
The assembly tool 21 is preferably made of plastic by injection molding and is placed on the covering element 4 with only slight space required, coaxially to the direction of activation of the switching element 2. Thus, even with switching elements 2 arranged alongside each other in recesses 20, the installation is possible with no problem. The inner profile 21a and the outer profile 4f are conically shaped in the axial direction of activation of the switching element 2, so as to intensify by axial pressure the forces transmitted in the circumferential direction by the assembly tool 21.
Advantageously, the inner profile 21a and the outer profile 4f are fashioned as gear teeth, and preferably the flanks of the teeth are steeper in the direction of disassembly, so as to apply a greater force with the assembly tool 21 when disassembling the covering elements 4.
Moreover, one notices from
Basically, it is also possible to do without the inner profile 21a of the assembly tool 21 and the outer profile 4f of the covering element 4 and configure the assembly tool 21 and the covering element 4 as conically increasing in the axial direction of activation of the switching element 2.
Besides the option depicted, it is also possible to configure the second microswitch 10 for continuous speed control of the drive units of a hoisting gear in the second switch stage by a Hall sensor interacting with a magnet. Such a special design for transformation of the movement path into an electric signal is known from DE 44 12 557 C2.
Suitable fields of use for such a two-stage switch include radio or cable-operated manual control units for cranes, construction machinery, or similar industrial machines.
Changes and modifications to the specifically described embodiments may be carried out without departing from the principles of the present invention, which is intended to be limited only by the scope of the appended claims as interpreted according to the principles of patent law including the doctrine of equivalents.
Number | Date | Country | Kind |
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102008057993.9 | Nov 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/064859 | 11/9/2009 | WO | 00 | 6/23/2011 |